Interference and How to Fix it
Interference and How to Fix it
Interference and Filtering
Electromagnetic compatibility is
Correct answer: B — the ability of equipment to function satisfactorily in its own environment without introducing intolerable electromagnetic disturbances
Electromagnetic Compatibility (EMC) is the discipline concerned with ensuring that electronic and electrical equipment can operate correctly in its intended electromagnetic environment, while at the same time not generating electromagnetic disturbances that would interfere with other equipment. EMC has two complementary aspects: immunity (a device must tolerate disturbances present in its environment) and emissions (a device must not itself produce excessive disturbances). In New Zealand, EMC requirements for equipment are administered by the Ministry of Business, Innovation and Employment (MBIE) under the Radiocommunications Act.
Therefore, EMC is correctly defined as the ability of equipment to function satisfactorily in its electromagnetic environment without itself causing intolerable interference to other equipment.
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On an amateur receiver, unwanted signals are found at every 15.625 kHz. This is probably due to
Correct answer: radiation from a nearby TV line oscillator
A frequency of 15.625 kHz corresponds to the horizontal line scanning frequency used in analogue television systems (625-line standard).
Nearby television receivers or monitors may radiate signals at this frequency and its harmonics, which can be picked up by an amateur receiver as unwanted interference.
These harmonics can appear across the tuning range at intervals of:
\[ 15.625\ \mathrm{kHz} \]
Therefore, the unwanted signals are likely caused by radiation from a nearby TV line oscillator.
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Narrow-band interference can be caused by
Correct answer: transmitter harmonics
Narrow-band interference is caused by signals that occupy a small range of frequencies.
Transmitter harmonics are discrete frequencies at integer multiples of the fundamental frequency, and therefore produce narrow-band interference.
Therefore, narrow-band interference can be caused by transmitter harmonics.
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Which of the following is most likely to cause broad-band continuous interference
Correct answer: D — poor commutation in an electric motor
Commutation is the process by which current is switched between the brushes and segments of a DC motor's commutator. When this switching is poor — due to worn brushes, a dirty commutator, or mechanical imbalance — it produces rapid, repetitive sparking. Each spark generates a broad-spectrum burst of radio frequency energy. Because sparking occurs continuously as the motor runs, the interference is both broadband (covering a wide range of frequencies simultaneously) and continuous in nature.
Therefore, poor commutation in an electric motor is the most likely source of broad-band continuous interference because the rapid, repetitive sparking at the commutator generates RF noise across a wide range of frequencies for as long as the motor is running.
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If broadband noise interference varies when it rains, the most likely cause could be from
Correct answer: B — outside overhead power lines
Overhead power lines are susceptible to rain because water alters the electrical characteristics of insulators, conductor surfaces, and any corroded or loose fittings along the line. Moisture can cause corona discharge, arcing across dirty or cracked insulators, and increased leakage currents — all of which generate broadband RF noise. Because this effect varies directly with rainfall, the interference level rises and falls with the weather, giving a clear clue that the source is an overhead line exposed to the elements.
Therefore, broadband noise that changes with rainfall is the classic symptom of wet-weather arcing or corona on outside overhead power lines.
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Before explaining to a neighbour that the reported interference is due to a lack of immunity in the neighbour's electronic equipment
Correct answer: C — make sure that there is no interference on your own domestic equipment
Before attributing a neighbour's interference problem to poor immunity in their equipment, you must first verify that your own station is not causing the issue. This means checking that your own domestic appliances and electronic equipment are not affected by your transmissions. If your own equipment is also experiencing interference, the problem likely originates with your station (e.g., excessive RF, spurious emissions, or poor filtering) rather than a lack of immunity in the neighbour's devices. Only once you have confirmed your own equipment is unaffected can you reasonably suggest the neighbour's equipment lacks adequate immunity.
Therefore, the correct first step is to confirm that your own domestic equipment is free of interference before suggesting the fault lies with your neighbour's equipment.
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A neighbour's stereo system is suffering RF break-through. One possible cure is to
Correct answer: D — use screened wire for the loudspeaker leads
RF breakthrough into audio equipment typically occurs because unscreened wiring — such as loudspeaker leads — acts as an unintentional antenna, picking up RF energy that is then rectified by semiconductor junctions inside the amplifier and heard as interference. Replacing those leads with screened (shielded) cable prevents the RF from being coupled into the audio circuitry in the first place. This is a fix applied at the affected equipment, which is the correct approach when the neighbour's device is susceptible.
Therefore, the most effective cure for RF breakthrough into a neighbour's stereo is to screen (shield) the loudspeaker leads so they no longer act as receiving antennas for the transmitted signal.
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When living in a densely-populated area, it is wise to
Correct answer: B — use the minimum transmitter output power necessary
In a densely-populated area, neighbouring households are close together, which increases the risk of transmitted interference (TVI/RFI) affecting televisions, radios, and other electronic equipment. Using only the power needed to make the contact keeps your signal at a level that gets the job done while minimising the chance of causing interference to nearby residents. This is both good amateur practice and consistent with New Zealand's Radiocommunications Regulations, which require operators to avoid causing unnecessary interference.
Therefore, using the minimum transmitter output power necessary is the correct and responsible approach when operating in a densely-populated area.
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When someone in the neighbourhood complains of TVI it is wise to
Correct answer: D — check your log to see if it coincides with your transmissions
TVI (Television Interference) complaints from neighbours require a methodical and cooperative response. The first step is to determine whether your amateur transmissions are actually the cause — and your station log is the best objective evidence available. If the times of reported interference do not coincide with your operating periods, your transmissions are unlikely to be the source. If they do coincide, further investigation (checking for spurious emissions, over-deviation, harmonic radiation, etc.) is warranted.
Good amateur practice — and the spirit of the NZART licence conditions — requires operators to take interference complaints seriously and investigate them in good faith before drawing any conclusions.
Therefore, the correct first action is to cross-reference the complaint with your station log to establish whether a correlation exists before taking any further steps.
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Cross-modulation is usually caused by
Correct answer: rectification of strong signals in overloaded stages
Cross-modulation occurs when a receiver stage is driven into non-linear operation by a strong signal. The overloaded device partially rectifies or mixes the strong signal with a weaker signal, causing the modulation from the strong signal to appear on the weaker one.
This is a receiver overload effect and indicates that an RF or IF stage is being driven beyond its linear range.
Therefore, cross-modulation is usually caused by rectification of strong signals in overloaded stages.
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When the signal from a transmitter overloads the audio stages of a broadcast receiver, the transmitted signal
Correct answer: can be heard irrespective of where the receiver is tuned
If a strong transmitted signal overloads the audio stages of a nearby broadcast receiver, it may bypass the normal tuning circuits and be detected directly by non-linear components in the receiver.
This causes the transmitted signal to be heard even when the receiver is tuned to other frequencies.
Therefore, the transmitted signal can be heard irrespective of where the receiver is tuned.
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Cross-modulation of a broadcast receiver by a nearby transmitter would be noticed in the receiver as
Correct answer: B — the undesired signal in the background of the desired signal
Cross-modulation occurs when a strong nearby transmitter overloads the early (RF) stages of a receiver, causing the receiver's amplifier or mixer to operate non-linearly. In this non-linear region, the modulation from the unwanted transmitter is transferred onto the carrier of the desired station — so the listener hears the wanted programme with the interfering signal audible in the background. The effect is most pronounced when a powerful transmitter is physically close to the receiver.
Therefore, cross-modulation from a nearby transmitter is heard as the unwanted signal audible in the background of the desired received signal, due to non-linear mixing in the receiver's front end.
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Unwanted signals from a radio transmitter which cause harmful interference to other users are known as
Correct answer: D — harmonic and other spurious signals
When a transmitter operates, it ideally radiates only on its assigned frequency. In practice, non-linearities in the transmitter stages can produce additional unwanted outputs — most commonly harmonics (integer multiples of the fundamental frequency) as well as other spurious emissions such as intermodulation products and parasitic oscillations. These unintended signals can fall on frequencies used by other services and cause harmful interference, which is why regulations strictly limit their level.
Therefore, unwanted transmitter outputs that can cause interference to other users are correctly termed harmonic and other spurious signals.
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To reduce harmonic output from a transmitter, the following could be put in the transmission line as close to the transmitter as possible
Correct answer: low-pass filter
Harmonics are unwanted signals at multiples of the transmitter’s operating frequency.
A low-pass filter placed in the transmission line near the transmitter allows the desired fundamental frequency to pass while attenuating higher-frequency harmonic components.
Therefore, harmonic output can be reduced by fitting a low-pass filter close to the transmitter.
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To reduce energy from an HF transmitter getting into a television receiver, the following could be placed in the TV antenna lead as close to the TV as possible
Correct answer: C — high-pass filter
Television reception in New Zealand uses VHF and UHF frequencies (roughly 174 MHz and above for digital terrestrial TV). HF amateur transmissions occupy frequencies below 30 MHz. A high-pass filter placed in the TV antenna lead passes the high-frequency TV signals while blocking the much lower HF frequencies, preventing the transmitter's energy from entering the receiver's front end and causing interference.
Therefore, a high-pass filter in the TV antenna lead is the correct solution, as it passes VHF/UHF TV signals freely while attenuating HF transmitter energy before it can reach the television receiver.
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A low-pass filter used to eliminate the radiation of unwanted signals is connected to the
Correct answer: output of the amateur transmitter
A low-pass filter used to suppress unwanted harmonic radiation must be placed where those harmonics are about to be radiated.
Harmonics are generated in the transmitter’s RF stages and appear at the output before being sent to the antenna.
Placing the filter at the transmitter output:
allows the desired fundamental frequency to pass
attenuates higher-frequency harmonic components before they reach the antenna
The balanced modulator operates at an earlier stage.
The stereo system is unrelated to RF transmission.
The mixer input is before RF amplification.
Therefore, the filter is connected to the output of the amateur transmitter.
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A band-pass filter will
Correct answer: C — attenuate frequencies each side of a band
A band-pass filter allows a specific range (band) of frequencies to pass through with little loss, while attenuating (reducing) signals both below and above that band. The band is defined by a lower and upper cut-off frequency, and signals outside this range are suppressed. Band-pass filters are widely used in receivers to select the desired signal and reject interference from other frequencies.
Therefore, a band-pass filter specifically attenuates frequencies on both sides of a chosen band, allowing only that band to pass.
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A band-stop filter will
Correct answer: pass frequencies each side of a band
A band-stop filter (also called a notch filter) is designed to attenuate a specific range of frequencies while allowing frequencies outside that range to pass.
This means:
frequencies within the stop band are reduced
frequencies above and below the stop band are passed
Stopping frequencies each side of a band describes a band-pass filter.
Allowing only one spot frequency through describes a very narrow band-pass filter.
Passing frequencies below 100 MHz is unrelated to the definition of a band-stop filter.
Therefore, a band-stop filter will pass frequencies each side of a band.
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A low-pass filter for a high frequency transmitter output would
Correct answer: A — attenuate frequencies above 30 MHz
A low-pass filter passes signals below its cut-off frequency and attenuates (reduces) signals above it. Fitted at the output of an HF transmitter, a low-pass filter with a cut-off around 30 MHz allows the desired HF transmission to pass while suppressing harmonic energy and other spurious signals that fall above 30 MHz. This is a standard requirement to prevent interference to other services from transmitter harmonics.
Therefore, a low-pass filter on an HF transmitter output attenuates unwanted harmonic and spurious energy above 30 MHz while allowing the intended HF signal to pass.
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Installing a low-pass filter between the transmitter and transmission line will
Correct answer: permit lower frequency signals to pass to the antenna
A low-pass filter allows signals below its cutoff frequency to pass while attenuating higher-frequency components.
In a transmitter system:
the desired fundamental frequency (lower frequency) is passed
higher-frequency harmonics are reduced
It does not pass higher frequencies.
It does not control SWR directly.
It does not regulate transmitter power output.
Therefore, a low-pass filter will permit lower frequency signals to pass to the antenna.
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A low-pass filter may be used in an amateur radio installation
Correct answer: B — to attenuate signals higher in frequency than the transmission
A low-pass filter passes frequencies below its cut-off frequency and attenuates (reduces) frequencies above it. In an amateur radio installation, a low-pass filter is commonly placed between the transmitter and the antenna feedline to suppress harmonics and other spurious emissions, which occur at frequencies higher than the intended transmission frequency. This helps prevent interference with television receivers and other services that operate at those higher frequencies.
Therefore, a low-pass filter is correctly used in an amateur installation to attenuate unwanted signals (such as harmonics) that are higher in frequency than the desired transmission.
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Television interference caused by harmonics radiated from an amateur transmitter could be eliminated by fitting
Correct answer: a low-pass filter in the transmitter output
Harmonics are unwanted signals at multiples of the transmitter’s operating frequency.
These higher-frequency harmonics may fall within television broadcast bands and cause interference if radiated by the transmitter.
A low-pass filter at the transmitter output allows the desired RF signal to pass while attenuating higher-frequency harmonic components.
Therefore, television interference caused by harmonics can be eliminated by fitting a low-pass filter in the transmitter output.
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A high-pass filter can be used to
Correct answer: prevent interference to a TV receiver
A high-pass filter allows higher frequencies to pass while attenuating lower frequencies.
In a transmitter system, it can be used to:
This helps prevent interference from lower-frequency transmissions entering a TV receiver system.
Therefore, a high-pass filter can be used to prevent interference to a TV receiver.
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A high-pass RF filter would normally be fitted
Correct answer: at the antenna terminals of a TV receiver
A high-pass RF filter allows higher-frequency signals to pass while attenuating lower-frequency signals.
In practice, it is used at a TV receiver input to:
pass TV broadcast frequencies (VHF/UHF)
block lower-frequency signals (e.g. HF transmissions) that could cause interference
A low-pass filter is used at a transmitter output.
The Morse key is not part of RF filtering.
Audio stages use audio-frequency filters, not RF filters.
Therefore, a high-pass RF filter is fitted at the antenna terminals of a TV receiver.
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A high-pass filter attenuates
Correct answer: D — low frequencies but not high frequencies
A high-pass filter passes signals above its cut-off frequency while attenuating (reducing) signals below that frequency. The name describes what it passes, not what it blocks — so a high-pass filter lets high frequencies through and rejects low frequencies.
Typical amateur radio applications include suppressing low-frequency interference or harmonic content below the desired band, or blocking DC and audio-frequency signals from an RF circuit.
Therefore, a high-pass filter attenuates low frequencies while allowing high frequencies to pass.
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An operational amplifier connected as a filter always utilises
Correct answer: negative feedback
An operational amplifier used as a filter always relies on negative feedback to control gain, stability, and frequency response. The feedback network, typically made from resistors and capacitors, determines the filter characteristics such as cutoff frequency, bandwidth, and response shape.
Negative feedback keeps the amplifier operating in a stable, linear region and prevents unwanted oscillation.
Therefore, an operational amplifier connected as a filter always utilises negative feedback.
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The voltage gain of an operational amplifier at low frequencies is
Correct answer: very high but purposely reduced using circuit components
An operational amplifier (op-amp) has an extremely high open-loop voltage gain at low frequencies, often:
\[ 10^5 \text{ to } 10^6 \]
In practical circuits, this gain is deliberately reduced using negative feedback components such as resistors.
This provides:
stable operation
predictable gain
improved linearity
The gain is not inherently low.
It is not less than one.
It is well-defined.
Therefore, the voltage gain is very high but purposely reduced using circuit components.
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The input impedance of an operational amplifier is generally
Correct answer: very high
An operational amplifier is designed to draw almost no input current so that it does not load the signal source. This results in a very high input impedance, often in the megaohm to gigaohm range for modern op amps.
A high input impedance allows accurate voltage amplification and prevents signal attenuation caused by loading effects.
Therefore, the input impedance of an operational amplifier is generally very high.
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An active audio low-pass filter could be constructed using
Correct answer: an operational amplifier, resistors and capacitors
An active low-pass filter requires an amplifying device along with frequency-selective components.
An operational amplifier used with resistors and capacitors can provide:
The resistors and capacitors determine the cutoff frequency, while the op-amp provides amplification and buffering.
Therefore, an active audio low-pass filter can be constructed using an operational amplifier, resistors and capacitors.
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A filter used to attenuate a very narrow band of frequencies centred on 3.6 MHz would be called
Correct answer: D — a notch filter
A notch filter (also called a band-stop or band-reject filter) is designed to attenuate a very narrow range of frequencies while passing all others. It is the opposite of a band-pass filter. Notch filters are commonly used in amateur radio to suppress a specific interfering signal or unwanted frequency — in this case, sharply rejecting signals centred on 3.6 MHz.
Therefore, a filter that sharply attenuates only a very narrow band of frequencies centred on a single frequency is correctly called a notch filter.
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